Inorganic cohesion agent for self-compacting cement pastes

ABSTRACT

The present invention relates to an inorganic cohesion agent for self-compacting cement pastes consisting of a co-precipitated SiO 2 /CaCO 3  mixture.

[0001] The present invention relates to an inorganic cohesion agent for self-compacting cement pastes.

[0002] Self-compacting concrete (SCC), which was developed in Japan in the eighties', is well known in literature (Okamura, H.; Kunishima, M.; Maekawa, K. and Ozawa, K.; High Performance Concrete based on the Durability Design of Concrete Structures, Proceedings of EASEC-2, Nr. 1, January 1989, pages 445-450). This self-compacting concrete consists of cement conglomerates whose fluidity (self-levelling), in the fresh state, is such that they can be used without any need for vibration or compacting stress.

[0003] These self-compacting cement pastes must have excellent properties both when fresh (fluidity, cohesion and absence of segregation), and in the hardened state (mechanical resistance and durability) . These characteristics can be obtained by contemporaneously adopting a low water/cement ratio, the use of super-fluidifying additives and the addition of cohesion or viscosizing agents.

[0004] The main characteristic of self-compacting concrete, as it is self-levelling, is an extremely high fluidity: this means that the slump test measurement is so high (>240 mm) as to be no longer significant; resort is therefore made to the slump flow measurement which must reach values of at least 600 mm.

[0005] The other essential characteristic of a self-compacting concrete, in addition to a considerably high fluidity, is the absence of bleeding and segregation. The absence of segregation is obtained by the addition of extremely effective mineral fillers such as, for example, silica fume and/or viscosizing agents of an organic nature, such as products based on modified cellulose.

[0006] As far as the properties in the hardened state are concerned, adequate mechanical resistance, in particular compression strength, and good durability of concrete structures can be obtained in a material with a high compacting degree.

[0007] The durability of concrete is correlated to the permeability in relation to the homogeneity of the phases of which it is composed (matrix, aggregate, transition zone). A reduced permeability of the material together with uniformity of the permeability values in the different zones of a cementitious end-product, indicate a good compacting degree.

[0008] There is no absolute measurement of a permeability coefficient, but there are various methods which measure different fluid transport mechanisms through the material. One of these methods is gas permeability, in particular air permeability.

[0009] The objective of the present invention is to identify an alternative agent to those existing in the state of the art for providing cohesion and compacting characteristics, thus obtaining a self-compacting concrete which contemporaneously has a high stability, viscosity and rest cohesion (i.e. absence of bleeding and segregation) and good compression strength values.

[0010] An object of the present invention relates to an inorganic cohesion agent for self-compacting cement pastes, consisting of a co-precipitated SiO₂/CaCO₃ mixture.

[0011] In particular, the composite material made up of the co-precipitated mixture of silica and calcium carbonates which forms the agent according to the present invention is obtained starting from natural or synthetic calcium silicates, crystalline or amorphous, hydrated or non-hydrated, or their mixtures, which, by reaction with CO₂ in water, can allow solid co-precipitated mixtures of SiO₂ and CaCO₃ to be obtained.

[0012] The starting materials can also be cements or cement clinkers.

[0013] The co-precipitated SiO₂/CaCO₃ mixtures according to the present invention can be used as such, as deriving from the production process, or in aqueous suspension, or they can be used in the dry state, after evaporation/separation of the whole or part of the water.

[0014] The co-precipitated SiO₂/CaCO₃ mixture according to the present invention preferably has a weight ratio SiO₂/CaCO₃ ranging from 1.2 to 0.1. It can contain up to 50% of other components in mass, among which calcium silicates (non-reacted or transformed), for example those indicated as CSH, and/or metallic oxides.

[0015] The specific surface measured with the BET method can range from 20 to 100 m²/g.

[0016] An example of a process for the production of silica and silica and calcium carbonate composites, starting from calcium silicates is described in the patent CA 1,122,779. This patent describes a process for the production of silica, in which calcium silicate crystals are put in contact with CO₂ in the presence of water and converted into silica, having the same configuration as silicate crystals, and into calcium carbonate particles attached to amorphous silica particles.

[0017] This SiO₂/CaCO₃ mixture (i.e. the mixture according to the patent) is preferably treated with inorganic acids in order to decompose the calcium carbonate, separate the calcium salts and obtain pure amorphous silica or it is used as such without any type of treatment or separation.

[0018] A further object of the present invention is a self-compacting concrete obtained with the use of an inorganic cohesion agent consisting of a co-precipitated SiO₂/CaCO₃ mixture.

[0019] The present invention also relates to recovery mortars and pastes which can be obtained by the use of an inorganic cohesion agent consisting of a co-precipitated SiO₂/CaCO₃ mixture.

[0020] The co-precipitated SiO₂/CaCO₃ mixture is preferably used in doses ranging from 1 to 30% with respect to the weight of the cement, in particular from 5 to 15%.

[0021] The main advantage of the agent according to the present invention lies in its being a cohesion agent which, as well as guaranteeing segregation-absence properties in the concrete better than or equivalent to those provided by the additives and/or mineral fillers normally used, at the same time allows the production of a long-lasting concrete with excellent compression strength.

[0022] In fact, although the use of some additives, such as precipitated silica alone or an organic viscosizing agent, on the one hand allows better cohesion of pastes in the fresh state, on the other hand it causes a drastic reduction in the compression strength with respect to a concrete with the same workability (free spreading), prepared with cement alone and without additives. Although concrete prepared with other mineral fillers such as calcareous fillers, has sufficiently high compression strength values (Rc), there are segregation phenomena in the fresh state. This segregation causes a lack of homogeneity in an end-product both during its laying and after hardening, with the formation of zones having different compacting degrees, thus showing different permeability values, in particular different air permeability coefficients.

[0023] The characteristics and advantages of the agent according to the present invention are better illustrated by the following detailed description, referring to the following examples.

DESCRIPTION OF THE ENCLOSED FIGURES

[0024] FIGS. 1-4 are a photographic representation of pastes 2, 3, 4 and 9 respectively, in the fresh state;

[0025]FIGS. 5, 6 and 7 are a photographic representation of pastes 1, 3 and 4 respectively, in the hardened state;

[0026]FIG. 8 is a photographic representation which shows in order test samples of pastes 1, 6, 4 and 3, after ejection;

[0027]FIG. 9 is a graph which represents a comparison between the compression strengths of pastes 1-8.

[0028] Nine pastes were in fact prepared, some of which containing the agent according to the present invention (pastes 1 and 2) and others containing additives according to the state of the art (pastes 3-9).

[0029] All the pastes were prepared with equal workability (slump flow ranging from 600 to 650 mm).

[0030] In particular, the materials with which the various pastes were prepared are the following:

[0031] cement: CEM I 52, 5 R ULTRACEM Italcementi;

[0032] aggregate: silico-calcareous SATAF, subdivided into five distinct sizes. The granulometric curve is of the discontinuous type with a maximum diameter equal to 20 mm; % with respect to Particle size Sand the total (mm) 113 10 0.1 ÷ 0.5 103 10 0.5 ÷ 2   109 20  8 ÷ 15 10-15 30 10 ÷ 15 15-20 40 15 ÷ 20

[0033] acrylic superfluidifying additive: 2000AC AXIM.

[0034] The concrete is prepared using a forced mixer with a vertical axis and the characteristics were evaluated by means of the following methods:

[0035] volume mass (kg/m³): UNI 6394 method, 1^(st) part;

[0036] free spreading (cm): slump test;

[0037] compression strength (MPa): EN 196/1 method; air permeability: on samples having Φ=8 cm and h=3 cm, taken from the upper part and from the lower part of cylindrical test samples (Φ=12 cm and h=40 cm), after 28 days of curing. The cylindrical test samples were obtained by filling appropriate cylindrical moulds with concrete, without vibration, and leaving it to harden in a vertical position. For the air permeability measurements, a Hassler-type cell was used, calculating the permeability coefficient k by means of the following equation (proposed by Grube and Lawrence): ${k = \frac{2{\eta \cdot L \cdot V_{2} \cdot P_{2}}}{\left( {p_{1}^{2} - P_{2}^{2}} \right) \cdot A}};$

[0038] wherein

[0039] k=permeability coefficient, m²;

[0040] η=viscosity of the fluid medium, N^(·)s^(·)m⁻²;

[0041] V₂=flow rate at the outlet, m^(·)s⁻¹;

[0042] P₁ and P₂=inlet and outlet pressure respectively, N^(·)m⁻²;

[0043] A=transversal surface of the test sample, m²;

[0044] L=thickness of the sample, m;

[0045] cohesion and segregation evaluation: this evaluation was effected both in the fresh state, by evaluating the cohesion of the paste after its preparation and the possible presence of bleeding, and also in the hardened state, by evaluating the internal segregation of cylindrical test samples (Φ=12 cm; h=40÷50 cm), specifically prepared without vibration and broken by indirect tensile stress after two days of hardening;

[0046] aesthetic evaluation: visual evaluation of the cylindrical test-samples, after hardening.

[0047] The cohesion agents present in pastes 1-9 of the following examples, are:

[0048] Paste 1: cohesion agent according to the present invention, co-precipitated SiO₂/CaCO₃ mixture alone;

[0049] Paste 2: cohesion agent according to the present invention, SiO₂/CaCO₃/CSH mixture;

[0050] Paste 3 and 3 bis: no cohesion agent;

[0051] Paste 4: Carrara calcareous filler (comparative)

[0052] Paste 5: commercial precipitated CaCO₃ (comparative);

[0053] Paste 6: commercial precipitated silica ULTRASIL VN3 (Degussa) (comparative);

[0054] Paste 7: Elkem 940 Silica fume (comparative);

[0055] Paste 8: commercial organic viscosizing agent (comparative);

[0056] Paste 9: no cohesion agent, but increase in the cement dosage.

EXAMPLE 1

[0057] A 20 liter paste was prepared with the following composition:

[0058] PASTE 1 (with the agent according to the present invention, co-precipitated SiO₂/CaCO₃ mixture alone) Weight Dosage Composition (kg) (kg/m³⁾ aggregate 38.000 1900 additions (SiO₂/CaCO₃ mixture) 0.600 30 Cement 8.000 400 paste water 3.700 185 acrylic additive 0.160 8.0 water*/cement ratio 0.48 water*/(cement + additions) ratio 0.44

[0059] Paste 1 has the following characteristics:

[0060] volume mass: 2405 kg/cm³;

[0061] free spreading: 63 cm; compression strength: see Table 1 below; segregation evaluation: see FIG. 5; aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance (FIG. 8).

[0062] The use of the co-precipitated SiO₂/CaCO₃ mixture alone, according to the present invention, with dosages ranging from 1 to 30% with respect to the weight of the cement, in particular from 5 to 15%, allows a cohesive and non-segregable system to be obtained, of extremely easy application in the self-compacting concrete field. TABLE 1 Rc (Mpa) Paste 1 day 2 days 7 days 28 days Paste 1 37.2 51.2 61.0 77.1 Paste 2 34.2 39.7 55.0 73.0 Paste 3 27.2 40.0 44.8 53.4 Paste 3 bis 39.8 41.8 51.1 65.0 Paste 4 39.4 43.5 50.3 61.5 Paste 5 39.2 51.0 55.0 68.9 Paste 6 32.6 38.4 49.2 55.7 Paste 7 21.3 33.6 39.2 63.5 Paste 8 4.4 14.0 24.2 31.8 Paste 9 33.4 46.7 55.5 66.2

EXAMPLE 2

[0063] A 20 liter paste was prepared with the following composition:

[0064] PASTE 2 (with the agent according to the present invention, SiO₂/CaCO₃/CSH mixture). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 additions (SiO₂/CaCO₃/CSH mixture) 0.600 30 Cement 8.000 400 paste water 4.200 210 acrylic additive 0.160 8.0 water*/cement ratio 0.54 water*/(cement + additions) ratio 0.50

[0065] Paste 2 has the following characteristics:

[0066] volume mass: 2373 kg/cm³;

[0067] free spreading: 60 cm;

[0068] compression strength: see table 1;

[0069] evaluation of the air permeability coefficient k (m²) on samples having (Φ=8 cm and h=3 cm, which form the upper and lower part of cylindrical test samples having Φ=12 cm and h=40 cm: see Table 2 below;

[0070] cohesion evaluation: see FIG. 1;

[0071] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance. TABLE 2 k (x 10⁻¹⁷ m²) Paste upper lower Paste 2 1.8 1.1 Paste 3 23.1 1.3 Paste 4 12.0 1.0 Paste 5 17.4 4.7 Paste 8 30.6 6.7

EXAMPLE 3

[0072] A 20 liter paste was prepared with the following composition:

[0073] PASTE 3 (without cohesion agent). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 additions — — cement 8.000 400 paste water 3.500 175 acrylic additive 0.136 6.8 water*/cement ratio 0.45 water*/(cement + additions) ratio 0.45

[0074] The composition of the paste was selected so as to have a paste with a high segregation in order to enhance the improvement obtained as a result of the cohesion additives.

[0075] Paste 3 has the following characteristics:

[0076] volume mass: 2443 kg/m³;

[0077] free spreading: 63 cm;

[0078] compression strength: see table 1;

[0079] cohesion and segregation evaluation: see FIGS. 2 and 6;

[0080] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance (FIG. 8).

[0081] Example 3 was subsequently repeated with a 20 liter paste having the following composition:

[0082] PASTE 3 bis (without cohesion agent). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 additions — — cement 8.600 430 paste water 3.800 190 acrylic additive 0.136 6.8 water*/cement ratio 0.45 water*/(cement + additions) ratio 0.45

[0083] Paste 3 bis has the following characteristics:

[0084] volume mass: 2429 kg/m³;

[0085] free spreading: 63 cm;

[0086] compression strength: see table 1;

[0087] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance.

EXAMPLE 4

[0088] A 20 liter paste was prepared with the following composition:

[0089] PASTE 4 (with Carrara calcareous filler). Weight Dosage Composition (kg) (kg/m³) aggregate 37.000 1850 additions (calcareous filler) 1.000 50 cement 8.000 400 paste water 3.500 175 acrylic additive 0.136 6.8 water*/cement ratio 0.45 water*/(cement + additions) ratio 0.40

[0090] Paste 4 has the following characteristics:

[0091] volume mass: 2444 kg/m³;

[0092] free spreading: 64 cm;

[0093] compression strength: see table 1;

[0094] cohesion and segregation evaluation: see FIGS. 3 and 7; aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance (FIG. 8).

[0095] It is evident from the photographs provided in FIGS. 3 and 7, that a calcareous filler is not capable of increasing the cohesion of a “segregable” concrete such as that of Example 3, represented in FIGS. 2 and 6.

EXAMPLE 5

[0096] A 20 liter paste was prepared with the following composition:

[0097] PASTE 5 (with precipitated CaCO₃). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 additions (precipitated CaCO₃) 0.480 24 Cement 8.000 400 paste water 3.700 185 acrylic additive 0.136 6.8 water*/cement ratio 0.47 water*/(cement + additions) ratio 0.45

[0098] Paste 5 has the following characteristics:

[0099] volume mass: 2339 kg/cm³;

[0100] free spreading: 63 cm;

[0101] compression strength: see table 1;

[0102] evaluation of the air permeability coefficient k (m²) see Table 2;

[0103] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance.

EXAMPLE 6

[0104] A 20 liter paste was prepared with the following composition:

[0105] PASTE 6 (with silica VN₃). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 additions (silica VN₃) 0.240 12 Cement 8.000 400 paste water 4.350 217.5 acrylic additive 0.160 8.0 water*/cement ratio 0.56 water*/(cement + additions) ratio 0.54

[0106] Paste 6 has the following characteristics:

[0107] volume mass: 2397 kg/cm³;

[0108] free spreading: 60 cm;

[0109] compression strength: see table 1;

[0110] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance (FIG. 8).

EXAMPLE 7

[0111] A 20 liter paste was prepared with the following composition:

[0112] PASTE 7 (with silica fume). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 additions (silica fume) 0.900 45 Cement 8.000 400 paste water 4.600 230 acrylic additive 0.160 8.0 water*/cement ratio 0.59 water*/(cement + additions) ratio 0.53

[0113] Paste 7 has the following characteristics:

[0114] volume mass: 2408 kg/cm³;

[0115] free spreading: 60 cm;

[0116] compression strength: see table 1;

[0117] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance.

EXAMPLE 8

[0118] A 20 liter paste was prepared with the following composition:

[0119] PASTE 8 (with organic viscosizing agent). Weight Dosage Composition (kg) (kg/m³) aggregate 38.000 1900 aggregate 38.000 1900 additions (organic viscosizing 0.008 0.4 agent Keiko-Krete) Cement 8.000 400 paste water 5.400 270 acrylic additive 0.160 8.0 water*/cement ratio 0.69 water*/(cement + additions) ratio 0.69

[0120] Paste 8 has the following characteristics:

[0121] volume mass: 2365 kg/cm³;

[0122] free spreading: 60 cm;

[0123] compression strength: see table 1;

[0124] evaluation of the air permeability coefficient k (m²); see Table 2.

EXAMPLE 9

[0125] A 20 liter paste was prepared with the following composition:

[0126] PASTE 9 (without a cohesion agent, but with an increase in the dosage of cement). Weight Dosage Composition (kg) (kg/m³) aggregate 36.000 1800 additions — — Cement 10.000 500 paste water 4.000 200 acrylic additive 0.170 8.5 water*/cement ratio 0.41 water*/(cement + additions) ratio 0.41

[0127] Paste 9 has the following characteristics:

[0128] volume mass: 2425 kg/cm³;

[0129] free spreading: 64 cm; compression strength: see table 1;

[0130] cohesion evaluation: see FIG. 4;

[0131] aesthetic evaluation: after ejection, the test sample has a good aesthetic appearance.

[0132] From a comparison of the previous data, the following can be observed.

[0133] Pastes 1 and 6, i.e. the pastes containing, as cohesion agent, the agent according to the present invention and commercial precipitated silica, do not undergo any decomposition in the absence of vibration, which on the contrary occurs with pastes 3, 4 and 9, as can be seen from FIGS. 1-4 and 5-7.

[0134] With the same workability with respect to pastes 1, 3 and 4, however, paste 6, i.e. with commercial precipitated silica, requires an increase in the paste water in the order of 25% and in the acrylic superfluidifying agent of 18%.

[0135] The use, on the other hand, of the co-precipitated SiO₂/CaCO₃ mixture, according to the present invention, limits the increase in the quantity of paste water to 13%. The influence in the water/cement ratio negatively influences the compression strength of concrete with commercial silica, i.e. paste 6. This effect, as can be seen from the graph in FIG. 9, is not observed for paste 1 which, for all the tests, has values similar to those of pastes 3 and 4.

[0136] This result is probably due to a rapid activation of the silica in the co-precipitated SiO₂/CaCO₃ mixture, together with a “filler” effect of the co-precipitated SiO₂/CaCO₃ mixture.

[0137]FIG. 8 shows that pastes 1 and 6 have the best finishing.

[0138] On comparing the compression strength values of the various pastes indicated in Table 1, it can be immediately seen how, with the same workability, pastes 1 and 2, i.e. the pastes containing the cohesion agent according to the present invention, have a very high compression strength with respect to the pastes with other additives according to the state of the art.

[0139] From the data provided in Table 2, it can observed that paste 2, containing the cohesion agent according to the present invention, has very low air permeability coefficient values and, above all, practically constant values at all points of the test sample. The pastes containing additives according to the state of the art, on the contrary, have extremely varying permeability coefficient values between different points of the test sample and this lack of homogeneity is a further confirmation of the fact that they do not have a good compacting degree.

[0140] The main advantage of the cohesion agent according to the present invention is that, in addition to guaranteeing non-segregation properties in the concrete which are better than or equivalent to those provided by the additives normally used, it also allows a long-lasting concrete to be obtained, with an excellent compression strength. 

1. An inorganic cohesion agent for self-compacting cement pastes, consisting of a co-precipitated SiO₂/CaCO₃ mixture.
 2. The cohesion agent according to claim 1, characterized in that the co-precipitated mixture of silica and calcium carbonates is obtained starting from natural or synthetic calcium silicates, crystalline or amorphous, hydrated or non-hydrated, or their mixtures, cements or cement clinkers.
 3. The cohesion agent according to claim 1, characterized in that the co-precipitated SiO₂/CaCO₃ mixture is in aqueous suspension.
 4. The cohesion agent according to claim 1, characterized in that the co-precipitated SiO₂/CaCO₃ mixture is in the dry state.
 5. The cohesion agent according to claim 1, characterized in that the co-precipitated SiO₂/CaCO₃ mixture has a weight ratio SiO₂/CaCO₃ ranging from 1.2 to 0.1.
 6. The cohesion agent according to claim 1, characterized in that the co-precipitated SiO₂/CaCO₃ mixture contains up to 50% of other components in mass.
 7. The cohesion agent according to claim 6, characterized in that the other components are calcium silicates (non-reacted or transformed), for example those indicated as CSH, and/or metallic oxides.
 8. The cohesion agent according to claim 1, characterized in that the specific surface of the co-precipitated mixture ranges from 20 to 100 m²/g.
 9. The cohesion agent according to claim 1, characterized in that the co-precipitated SiO₂/CaCO₃ mixture is present in dosages ranging from 1 to 30% with respect to the weight of the cement.
 10. The cohesion agent according to claim 1, characterized in that the co-precipitated SiO₂/CaCO₃ mixture is present in dosages ranging from 5 to 15% with respect to the weight of the cement.
 11. The cohesion agent according to claim 1, which can be obtained by means of a process for the production of silica, in which calcium silicate crystals are put in contact with CO₂ in the presence of water and converted to silica, having the same configuration as silicate crystals, and to calcium carbonate particles attached to amorphous silica particles.
 12. Use of the agent according to any of the previous claims, for self-compacting cement pastes.
 13. Self-compacting concrete obtained with the use of an inorganic cohesion agent according to any of the claims from 1 to
 10. 14. Recovery mortars or pastes obtained by the use of an inorganic cohesion agent according to any of the claims from 1 to
 10. 